Functionally Gradient Material Fabrication Based on Cr, Ti, Fe, Ni, Co, Cu Metal Layers via Spark Plasma Sintering

The paper presents a method of obtaining functionally graded material (FGM) of heterogeneous (layered) type based on joined metals Cr-Ti-Fe-Co-Ni-Cu using spark plasma sintering (SPS) technology. The structure, elemental and phase composition of FGM obtained on the basis of joined metals with differ...

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Veröffentlicht in:	Coatings (Basel) 2023-01, Vol.13 (1), p.138
Hauptverfasser:	Shichalin, Oleg O., Papynov, Evgeniy K., Buravlev, Igor Yu, Buravleva, Anastasiya A., Chuklinov, Sergey V., Gridasova, Ekaterina A., Pogodaev, Anton V., Nepomnyushchaya, Valreiia A., Kornakova, Zlata E., Lembikov, Alexey O., Gritsuk, Danila V., Kapustina, Olesya V., Gribanova, Sofia S., Shi, Yun
Format:	Artikel
Sprache:	eng
Schlagworte:	Alloy systems Chromium Cobalt Composite materials Cooling Copper Diamond pyramid hardness Functionally gradient materials Gas turbine engines Grain size Graphite Heat Industrial applications Iron Mechanical properties Nickel Particle size Phase composition Plasma sintering Radiation Spark plasma sintering Thermal expansion Titanium
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creator	Shichalin, Oleg O. Papynov, Evgeniy K. Buravlev, Igor Yu Buravleva, Anastasiya A. Chuklinov, Sergey V. Gridasova, Ekaterina A. Pogodaev, Anton V. Nepomnyushchaya, Valreiia A. Kornakova, Zlata E. Lembikov, Alexey O. Gritsuk, Danila V. Kapustina, Olesya V. Gribanova, Sofia S. Shi, Yun
description	The paper presents a method of obtaining functionally graded material (FGM) of heterogeneous (layered) type based on joined metals Cr-Ti-Fe-Co-Ni-Cu using spark plasma sintering (SPS) technology. The structure, elemental and phase composition of FGM obtained on the basis of joined metals with different values of the temperature coefficient of linear expansion (CTLE) were studied by SEM, EDS and XRD methods with regard to the phase states of the alloy system. Based on the Vickers microhardness data, the evaluation of the mechanical characteristics of FGM in the whole sample body and locally at the contact boundaries of the joined metals was carried out. The results of the study are new and represent a potential for FGM, as well as functionally graded coatings (FGC), which have special physical, chemical and mechanical properties and are highly demanded for the manufacture of structures and products for industrial applications.
doi_str_mv	10.3390/coatings13010138
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The structure, elemental and phase composition of FGM obtained on the basis of joined metals with different values of the temperature coefficient of linear expansion (CTLE) were studied by SEM, EDS and XRD methods with regard to the phase states of the alloy system. Based on the Vickers microhardness data, the evaluation of the mechanical characteristics of FGM in the whole sample body and locally at the contact boundaries of the joined metals was carried out. 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subjects	Alloy systems Chromium Cobalt Composite materials Cooling Copper Diamond pyramid hardness Functionally gradient materials Gas turbine engines Grain size Graphite Heat Industrial applications Iron Mechanical properties Nickel Particle size Phase composition Plasma sintering Radiation Spark plasma sintering Thermal expansion Titanium
title	Functionally Gradient Material Fabrication Based on Cr, Ti, Fe, Ni, Co, Cu Metal Layers via Spark Plasma Sintering
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